DE3131853C2 - Method and circuit arrangement for recording and / or reproducing broadband signals - Google Patents

Abstract

A method for storing broadband signals in at least two narrowband channels is specified. The circuit arrangement for carrying out the method comprises a plurality of memory devices with different write-in and read-out clock rates for changing the time base of the signals intended for storage. The original signals are preferably split into a part with a large and a part with a small bandwidth requirement and the parts with a large bandwidth requirement are stretched in time and the parts with a small bandwidth requirement are compressed in time and both types of signals are recorded in at least two channels after the time base change.

Description

have a lasting impact. At the same time making it a desirable one Simplification given for slow-motion or fast-motion playback. The context in the Alignment of the sync pulses are also in an article by F. T. Bakeers and J. H. Wisseis under the Title "An experimental apparatus for recording television signals on magnetic tape" in Philips Technical Review, VoI. 24, No. 3, pages 81 to 83, 1962.

DE-AS 26 29 706 also discloses a method for transmitting and / or recording color television signals known, in which the color information is time-compressed is transmitted and / or recorded line-sequentially during the horizontal blanking interval, whereby a broadband luminance designa! and ensure reliable synchronization shall be. The luminance information is used for about 80% of the line duration and the color information time-compressed line-sequentially during the horizontal blanking interval of a standardized color television signal transfer. Furthermore, the color signals are used for most of the remaining 20% of the line duration transmitted or recorded. The known method offers an improvement in resolution and lower color falsifications because amplitude errors occurring during transmission or recording at best make themselves noticeable as a color saturation error, but not as a chromaticity error. Because of the sequential Transmission of the color difference signals as a result of the single-channel processing is subject to the known However, the method has noticeable limitations in terms of resolution in color reproduction.

It is also known from DE-OS 27 45 337, the bandwidth requirements when recording broadband To reduce signals by dividing these signals one after the other into n groups and in multiple channels can be recorded. However, this is a dynamic memory with several parallel tracks in the longitudinal direction of the magnetic tape.

From the Γ.Έ-AS 23 47 148 is a circuit arrangement for converting a broadband simultaneous image signal into a narrow band partial image sequence signal known, in which the two components of the chrominance signal that are simultaneously present in the broadband simultaneous image signal compressed by time base change to half the duration of the luminance signal and in the The narrow transmission path can be transmitted sequentially together with the luminance signal. The known circuit arrangement is only for the transmission of individual or per terrestrial individual images suitable, but not for the continuous recording of "moving" television scenes without loss of resolution, since the single-channel narrow-band transmission of an original broadband simultaneous image signal is essential requires more time. There is also only a fixed compression ratio of 1: 2 for the chrominance components possible without gaps in the signal.

From DE-AS 20 56 684 a system for storing color image signals is also known, in which a luminance signal and a comparatively narrower chrominance signal are recorded on a track of a recording medium. During part of the line period, the chrominance signal belonging to this line period is recorded in a time-compressed manner instead of the luminance signal, and the corresponding luminance signal is recorded during the remaining part of the line period. With the known system, interference between the luminance and chrominance signals can be avoided because these signals are never recorded at the same time, but the transmission bandwidth of a given transmission channel can be exceeded because of the unchanged large or, in the case of time-compressed recording, increased bandwidth requirements of the luminance signal so that the reproduced image is reduced in resolution
Finally, it is known to record the audio information belonging to the television signal in a time-compressed manner either in separate memory tracks (DE-OS 30 33 165) or in blocks at the beginning or at the end of a video recording track (DE-OS 29 21 892). The video information can also be recorded with time compression. In both cases, no reduction in yields of the large bandwidth requirement for the luminance signal, so that it is only partially stored or transmitted eite ^r in a channel with lower Übertragungsbandb.

The invention is therefore based on the object, through the choice of any desired compression ratios for the components of the chrominance signal. * and expansion ratios of the luminance signal, the transmission bandwidth of the available transmission channels to be used optimally in each case and by the cyclically alternating recording in at least two spatially separated channels to avoid gaps in the signal.

The solution to this problem takes place with the specified in the characterizing part of the main claim Measures.

The method according to the invention with the characterizing features of the main claim has on the other hand the advantage that the available storage area on the recording medium is used as completely as possible can be, whereby the signals by appropriate time transformation to approximately the same bandwidth can be brought. Another advantage is that the crosstalk between the individual Recording channels is reduced.

D'irch those listed in the subclaims Measures are advantageous developments and improvements of the stated in the main claim Procedure possible. It is particularly advantageous that the complete color information of each line. Together is stored with the corresponding brightness signal and both pieces of information are therefore also stored in the Playback of every television line are available.

Exemplary embodiments of the invention are shown in the drawing and in the description below explained in more detail. It shows

F i g. 1 shows a schematic representation of a head wheel of a magnetic tape device for use in the inventive System.

Fig. 2 schematically shows a track image on a * magnetic tape recorder, recorded by a head wheel according to Fig.l.
F i g. 3 as a block; illustration of an exemplary embodiment of a circuit arrangement according to the system according to the invention,

4 shows a time scheme to explain the temporal Correlation in signal processing by means of the circuit arrangement according to FIG. 3,

5 shows, as a block diagram, another exemplary embodiment of a circuit arrangement,

F i g. 6 shows the timing diagram to explain the temporal relationship during signal processing by means of FIG

Circuit arrangement according to FIG. 5.

In Fi g. 1, a magnetic tape 10 is guided by deflection elements 11, 12 around a head wheel 13 that it does this wraps around at an angle of about 180 °. The magnetic tape 10 describes half a helix, so that the Arranged on the head wheel 13 magnetic heads 1.1, 1.2, 2.1 and 2.2 the magnetic tape 10 in a sequence of Describe track sections arranged obliquely to the tape edge. These relationships are shown in FIG. 2 closer explained. Of the magnetic heads arranged on the head wheel 13, the heads 1.1 and 2.1 each form and 1.2 and 2.2 a recording and playback channel, respectively. The diametrically opposed to each other Magnetic heads are so electrically connected to one another that they are each electrical at the same time Receive signals for recording on the magnetic tape, or scan the magnetic tape during playback and record similar signals.

The real arrangement of the magnetic heads on the Head wheel 13 will be explained below with the aid of the track arrangement in FIG. The magnetic tape 10 in Fig. 2 is at a constant speed by known and therefore not further The drive devices shown are transported in the longitudinal direction of the belt, for example in the direction of arrow 21. The head wheel 13 with the magnetic heads attached to the circumference rotates rapidly in the direction of arrow 14, as a result of the incline of the magnetic tape during the 180 ° wrap on the magnetic tape 19 a sequence of magnetic tracks 25 can be written. These traces are shown in FIG. 2 with the reference numerals of the magnetic heads producing them, and it can be seen that the recording sequence follows 4 tracks repeated each time. The direction of recording on the magnetic tape is indicated by arrow 26 indicated.

The magnetic head pairs 1.1. 2.1 and 1.2. 2.2 are on the head wheel 13 by a certain angular amount in the Level of the head wheel offset from one another. The two pairs of magnetic heads are still perpendicular to the plane of the drawing offset in height from one another in such a way that the diametrically opposed Rotate magnetic heads in the same plane. The size of the angular offset in the head gear plane and the vertical offset perpendicular to this result mainly from the desire to write 10 tracks on the magnetic tape, giving way to the existing ones Use storage space as completely as possible. Depending on the choice of the peripheral speed of the head wheel, its Diameter, the width of the magnetic tape and its transport speed, the offset is selected so that that the individual tracks 25 always begin as close as possible to the tape edge and stop before this. It is also desirable to record the tracks without any safety gaps between the individual tracks. to further increase the recording density. To the discussion between the individual To suppress track sections as possible, the arrangement is like this in the present exemplary embodiment made that the magnetic heads of a recording channel have a different angle of the head gap than that of the other recording channel (Fig. 2). Consequently does not occur if you accidentally partially pass over a section of the track provided magnetic head a strong attenuation of the signals from the adjacent track due to the angular deviation on. This effect is known in the art as azimuth damping.

To reduce the crosstalk interference from one track section to the next, i.e. from one channel to the others, to be suppressed further, the track arrangement can be made so that, as indicated at 27 in FIG. the synchronous components in the signal characterized by large amplitude values or the same frequencies lying next to each other.

In the schematic representation of the recording method according to the invention according to FIG. 3, the composite signal intended for recording is fed to inputs 31 and 32 after division by means of a filter arrangement (not shown) into a luminance part (L) and a chrominance part (C). The brightness signal (luminance signal) L is applied to input 31 and the chrominance signal (chrominance signal) C is applied to input 32. By means of the switching devices 33,34, the signals at the inputs 31,32 are alternately sent to the storage devices 35, 36 b ^7w ^ 35 «pCT #» Hf »n Hip Διίςσϋησρ Hpr Snnirhprpin directions 35 and 37 are each connected to a switching contact of a further switching device 39, while the outputs of the storage devices 36, 38 are each connected to a switchover contact of a switchover device 40 of the same type. The center pole of the switching device 39 is connected to the signal coil of a first magnetic head 1.1, the center pole of the switching device 40 is connected to the signal coil of a second magnetic head 1.2.The magnetic heads 1.1 and 1.2 are in operative connection with the surface of the magnetic tape 41 for magnetic storage of the electrical signals supplied to them.

In an analogous way take both de; · Playback - like in the right half of FIG. 3 shown - the magnetically effective parts of the magnetic heads 1.1 and 1.2 the signals stored in (invisible) tracks on the magnetic tape. After conversion to electrical Signals in the signal coil associated with each magnetic head are transmitted via switching devices 39, 40 alternately given to storage devices.

The signals from the magnetic head 1.1 pass alternately via the switching device 39 to the storage devices 35,37, the signals picked up by the magnetic head 1.2 via the switching device 40 alternately to the storage devices 36, 38. The outputs of the storage devices 35,36 are each connected to a switching contact Switching device 33, the outputs of the storage devices 37, 38 each to a switching contact of the switching device 34. A coherent luminance signal (L) is then applied to the common pole of the switching device 33, and a coherent chrominance signal (C) is applied to the common pole of the switching device 34. *

The memory devices 35,36,37,38 are advantageously selected to achieve a simple circuit configuration memory arrangements with independent read-in and read-out clock rates, for example those of the CCD type Save TV line. The luminance signal L filtered out of the standardized FBAS signal is alternately fed to the storage devices 35 and 36 by means of the switching device 33 from the input 31. As a result, the brightness component L of a line in the memory 35, the brightness information of the

the next line is written into the memory 36, etc. At the same time, the same switching frequency the switching device 34 is actuated, by means of which the chrominance component C from the input 32 alternately the memory 37.38 is given. For reading out the signal sections contained in the storage devices 35, 36 of line length with the Helligwits information contained therein, a clock rate is selected which is less than the one used for storing by a factor of 1.5. As a result, the length of time is for the readout process is 1.5 times longer, so the individual signal sections are compared to the Reading in stretched over time. For reading out the signal sections c contained in the storage devices 37, 38 of line length with the information content of the chrominance signal, a clock rate is selected which is larger by a factor of 2 than that used for storing. As a result, the readout process takes time only the groves of the time used to write, the individual signal sections are thus compressed in time.

By means of the switching device 39, the brightness signals labeled L ' , which are temporally stretched by a factor of 1.5 compared to the original length, and the signal sections labeled C , which are shortened to half the original length with the chrominance signal of the signal coil of the magnetic head 1.1 are alternately supplied and on the Magnetic tape stored in related track sections. In the same way, the time-stretched signal parts L ' taken from the storage system 36 and the signal parts C read from the memory system 38 are combined by means of the switching device 40 and stored by the magnetic head 1.2 in a second sequence of associated track sections on the magnetic tape 41.

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the embodiment described above are chosen arbitrarily. However, they result with advantage from the assumption that the bandwidth requirement for the brightness signal L to the bandwidth requirement for the chrominance signal C is approximately 3: 1. To store the brightness information L , a recording channel with three times the bandwidth requirement compared to the recording channel for the chrominance signal C would have to be available without changing the time base or, if both recording channels are designed the same, the channel occupied with the chrominance C is only about a third exploited. Due to the time expansion of the signal sections with the brightness information L , the bandwidth requirement for their recording goes down from 3 to 2 MHz, for example; the compression of the signal sections with the chrominance signal C also increases the bandwidth requirement from approx. 1 MHz to 2 MHz. As a result, a recording channel designed for a bandwidth of 2 MHz is optimally used for storing both the brightness component L and the color component C

As already indicated, FIG. 3 only those necessary to explain the basic mode of operation Circuit elements. In the schematic representation, those available in conventional technology are therefore missing Signal processing circuits such as amplifiers, limiters, as well as those for controlling the Switching devices 33,34,39,40 necessary clock generating devices not shown However, their structure and mode of operation are within the scope of ability of an average person skilled in the field of magnetic storage technology, so that here on their detailed Representation can be dispensed with.

In Fig. 4, the signal sections present at inputs 31 and 32 are labeled L 1, L 2, L 3 ... and C1, C2, C3 ... After the signals Ll, L2, L3, etc., the storage devices 35,36 and the signal sections Cl, C2, C3 with the chrominance information have passed through the memories 37, 38 and by means of the

ίο switching devices 39 alternate the outputs of the storage devices 35, 37 and, by means of the switching devices 40, the outputs of the storage devices 36,38 are connected to the signal coils of the magnetic heads 1.1 and 1.2, the result is a two-channel Signal flow of the form that in channel 1 the luminance and chrominance signal sections provided with odd indices are included, the signal sections with the brightness information L ... for Purpose of the Banubreitiverringeiuiig iciiücu gcdchni and the signal cuts with the chrominance information C ... to achieve the highest storage density in terms of time are compressed.

In the same way, the outputs of the storage devices 36, 38 are alternately sent to the signal coil of the magnetic head 1.2 by means of the switching device 40 and thus alternately signal sections L ... with the brightness information and signal sections C ... with the chrominance information in a second channel recorded. The tracks on the magnetic tape are advantageously arranged in such a way that the boundaries between the signal sections in adjacent tracks are opposite one another, so that similar information is stored in adjacent track sections, which reduces the adverse influence of crosstalk. During playback, the two parallel Ι ^ απαΐΑη aiifofii ^ iiifHnfitpn ^ icrnnlahcr ^ hnittp mittpl «: erp-

Appropriate clock controls of the storage devices 35 to 38 and the switching devices 33, 34, 39, 40 brought back to the original length and two continuous signal trains L 1, L2, L3 ... and Cl, C2. C3 summarized. As a result of the time transformation in the storage devices 35 to 38, a basic delay occurs after playback. which must be taken into account when determining the recording pattern on the magnetic tape.

In the embodiment of Figure 5, the memory arrangements 51, 52, 53, 54 of the CCD type (Charged Coupled Devices) are controlled with different clock rates Clock rates are in the ratio 2: 3: 4. The inputs of the storage devices 51 to 54 are each connected to the line 71 by a switching device 61, 62, 63, 64, which brings in the information on the brightness or luminance (L) The inputs of the switching devices 51 to 54 are connected to a second line 85 which contains the chrominance information or chrominance (C) .

During playback, there are inputs and outputs of the storage devices 51 to 54 interchanged and the clock control at the clock inputs takes place from Clock sources with clock rates in a ratio of 13: 2: 3

stand. Otherwise, the display device is strictly mirror-symmetrical to the recording device, so that the individual components do not have to be explained in more detail.

The mode of operation of the recording and reproducing device according to FIG. 5 will be explained in the following in connection with the timing diagram of FIG. The incoming signal sections on lines 71, 85, each line length with the brightness information (line 71) or chrominance information (line 85) are connected via the switching devices 61, 62, 63, 64 or 81, 82, 83, 84 to the inputs of the Storage devices 51, 52, 53, 54 connected. Corresponding to lines a, b , the luminance signal L is contained in one channel and the chrominance signal C is contained in the other channel. If the switching device 61 is closed for the duration of a television line, the brightness information is corresponding to this one television line

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at the same time, the switch of the switching device 55 labeled 3 / connects the clock input of the memory device 51 to the clock source, which supplies the average clock rate from the clock rate ratio 2: 3: 4. When the writing of the brightness information L 1 in the memory device 51 is finished. so the clock input of the memory device 51 is now connected to the clock source, which supplies a clock rate which is lower by a factor of 0.66. At the same time, the switching device 86 is switched so that the output of the switching device 51 is connected to the magnetic head 1.1. Reading out the brightness information of a television line contained in the memory device 51 now takes 1.5 times the time in accordance with the lower clock rate when reading out, ie the time base is stretched and the bandwidth requirement for storage is reduced.

As can be seen from the timing diagram in FIG. 5a can be seen, the writing of the chrominance information takes place each line with the same clock rate with which the readout of the luminance information from the memory device he follows

When using the shear register principle, it is therefore possible to write other information into the memory device at the same time as it is read out, provided that this is to take place at the same clock rate. As a result, it is possible to write the chrominance information C into this memory by closing the switch 81 and opening the switch 60 at the same time as the brightness information Z / l is read out from the memory 51 (FIG. 6c). A part of the signal section C3 (FIG. 6b) is also written into the memory, but this circumstance is without disadvantage, since the excess information is suppressed during the subsequent readout by corresponding clock switching. The signal segment pairs L'2 / C3. Z / 3 / O4, L'4 / C5 ... according to the time scheme in FIG. 6c to f from the two signal trains L 2, L 3, L 4 ... and C3, C 4, C5 ... (Fig. 6a, b) and obtained by switching the switching devices 86, 87 to two consecutive ones Signal trains with the same bandwidth requirements for luminance and chrominance information combined (Fig. 6g, h). These two signal trains are recorded on the magnetic tape 10 by the two magnetic heads 1.1 and 1.2. it

The playback operation takes place with a reciprocal time transformation of the signal sections stored on the magnetic tape to. This is achieved by a corresponding clock control of the storage devices 51 to 54. Thus, according to FIG. 6g, the signal section Z / 1 with the luminance information is first read into the memory device 51 after the switching device 85 has connected the memory input to the signal coil of the magnetic head 1.1. The read-in clock rate is marked with 2 /, i.e. it is exactly the same as the read-out clock rate during the recording process. When the entire information Z / l is contained in the memory 51, its clock input is connected to the clock source with the clock rate 3f , so that the subsequent read-out process takes place at 1.5 times the speed of writing. The signal section therefore appears at the output of the memory device 51 in the original length L 1 (FIG. 6i) at the same time as the luminance information is read out, the chrominance information C "2 subsequently recorded on the magnetic tape in the same track is stored in the memory at the same clock rate After the writing, the clock input of the memory device 51 is switched over again and the chrominance information contained in it is read out at a clock rate that is half that of the writing and thus brought back to the original length C2 (FIG. 6i). .t devices 61, 81 the signal sections with alternating luminance and chrominance information which are present one after the other at the output of the memory device 51 are distributed to lines 71 and 85 in such a way that line 71 contains the continuous luminance information and line 85 contains the continuous chrominance information. To this For this purpose, the outputs of the storage devices 52 to 54 can also be connected in parallel to the lines 71 and 85 in the same way. After assembling the signal sections L 1 / C2, L2IC3, L 3 / C4 ... (Fig. 6i to m) to form the two signal trains with the luminance information (L 1, Z, 2, Z.3 ...) or chrominance information CCl. C2, C3 ...) (Fig. 6n), the storage process is complete.

For this purpose 4 sheets of drawings

Claims (5)

Patent claims: 1. Method for recording and / or reproducing broadband signals, in particular of color video signals, the signals being split into a component when recorded with a larger and one with a lower bandwidth requirement as well as a temporal one Subdivision into sections of a certain length, characterized in that that both types of signal sections are subjected to opposing time base changes, the sections of greater bandwidth requirement being stretched in time and the signal sections being smaller Bandwidth requirements are compressed in time and that the signal sections changed in the time base cyclically alternating in at least two spatially separated channels of a magnetic .Memory are recorded in such a way that there is a temporal overlap in each of the channels of signal sections is avoided, and that the multi-channel recorded signals during playback converted back to the original frequency position by reciprocal time base change and closed can be assembled into a signal corresponding to the original signal. 2. The method according to claim 1, characterized in that the one brightness and one Color component split color video signal storage device is supplied to which when reading or reading out clock signals of different frequencies are supplied, and Cdß the outputs of the Storage devices for changing the time base of the signal sections with the financial information and the outputs of the storage devices for the time base change of the signal sections with the Chrominance information switched alternately to at least two magnetic converter devices will. 3. Circuit arrangement for carrying out the method according to claim 1, characterized by memory devices (35, 36, 37, 38; 51, 52, 53, 54) which are switched by first switching devices (33, 34; 61, 62, 63, 64; 81 , 82, 83, 84) alternately or cyclically with input lines (31, 32; 71, 85) with the signal sections of the brightness information (L) and the chrominance information (C) can be connected and to carry out the time base changes with Einlesebzw. Read-out clock signals of different frequencies can be acted upon, and by second switching devices (39, 40; 86, 87) for connecting the outputs of the storage devices with at least two magnetic converters (1.1,1.2) for recording the signals from the original signals of the lines (Sl, 32,71 , 85) obtained signals. 4. Circuit arrangement according to claim 3, characterized by a number of clock signal sources, which by switching devices (55, 56,57,58) with the clock inputs of the storage devices (51,52,53,54) are connectable. 5. Schnllungscinrichlungcn according to claim 3 or 4, characterized in that the clock rates of the Takiquellcn for the recording process the ratio 2: 3: 4 and a ratio of 1.5: 2: 3 for playback. The invention is based on a method for recording and / or reproducing broadband Signals, in particular color video signals, according to the preamble of the main claim. The continuing drive to increase the density of magnetic tape recorders of color television signals has led to the introduction of a number of measures, each of which a certain contribution to the realization of this task to LieferL The known measures can be roughly divided into two categories: The first category of solution measures deals with increasing the usable frequency bandwidth of a given Magnetic tape device type or the reduction of the necessary relative speed between the or the magnetic transducers and the magnetic recording medium while maintaining the highest transmittable upper limit frequency. By reducing the relevant dimensions for magnetic converters and by improving the magnetic properties of the recording media, up to one reduce the smallest wavelengths to be recorded even further, whereby the above effect occurs Another measure to increase the storage density while maintaining the recording quality with at the same time low demands on the mechanical and electrical properties of the magnetic tape recorder is the technique used for a long time to convert the on a subcarrier into Quadrature modulated chrominance signals in a frequency band, which is at the lower limit of the frequency modulated Brightness signal connects. Such a method is known from DE-OS 18 08 539, in his However, difficulties arise due to the fact that when recording the in the frequency converted subcarrier with the amplitude necessary to achieve a sufficient signal-to-noise ratio Harmonics break through into the frequency band of the brightness signal and lead to picture disturbances (Color noise). A second category of methods for increasing the storage density when storing signals is on magnetic tape by dividing the color television signals into a luminance signal and a chrominance signal and their separate recording in separate recording tracks. Here is the arrangement so made that the first kind of signals and the second kind of signals by separate recording magnetic heads be transmitted. Such a method is described in DE-OS 19 35 109. The arrangement is such that the first type and the second type of tracks are at least partially overlap, the core gaps of the magnetic heads of the first and the second type include an angle in the plane of the magnetic tape (azimuth recording). In DE-OS 14 74 268 a magnetic tape recorder / ur television recording is described in which a Ma- M) gnetband moved helically around a scanning device, in which cm head wheel with two diametrically opposed to each other opposing magnetic heads rotates. To suppress the gap when recording / wipe the individual traces occurring b5 crosstalk, the sync pulses of adjacent tracks are arranged so that they are also in the event of deviations of the magnetic head of the track during playback does not synchronize the reproduced image